A Conserved C-Terminal Region in Gp71 of the Small Isometric-Head Phage LL-H and ORF474 of the Prolate-Head Phage JCL1032 Is Implicated in Specificity of Adsorption of Phage to Its Host,
            <i>Lactobacillus delbrueckii</i>

Равин, В. К.; Räisänen, Liisa; Alatossava, Tapani

doi:10.1128/jb.184.9.2455-2459.2002

Cited by 38 publications

(39 citation statements)

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“…We have previously suggested that there are at least three types of receptors for L. delbrueckii phages: two specific for LL-H and its host range mutant LL-H-a21 and one specific for the phage JCL1032 (23). In this study, we demonstrate that these L. delbrueckii phages are inactivated by purified LTAs from L. delbrueckii subsp.…”

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confidence: 57%

“…As far as we know, LL-H-a21 differs from LL-H only by a single amino acid in the receptor binding protein Gp71, thus suggesting that the specificity of inactivation reactions resides in the Gp71-LTA interaction (23). Like LL-H-a21, JCL1032 reacted with the LTAs examined in this study, although more LTAs were needed for significant inactivation.…”

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confidence: 81%

“…Ads-5, one of the LL-H-resistant mutants of L. delbrueckii subsp. lactis ATCC 15808, is able to block the adsorption of LL-H but not the adsorption of the LL-H host range mutant LL-H-a21 or JCL1032 (23). In this study, we investigated if purified LTAs isolated from ATCC 15808 and Ads-5 could serve as a receptor substance in the early stage of L. delbrueckii phage infections.…”

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confidence: 99%

“…Both phages have noncontractile tails, and their genetic determinants involved in host recognition have been characterized. Gp71 and its homolog ORF474 determine the adsorption specificities of LL-H and JCL1032, respectively (23). Ads-5, one of the LL-H-resistant mutants of L. delbrueckii subsp.…”

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confidence: 99%

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Characterization of Lipoteichoic Acids asLactobacillus delbrueckiiPhage Receptor Components

Räisänen

Schubert²,

Jaakonsaari

et al. 2004

J Bacteriol

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Lipoteichoic acids (LTAs) were purified from Lactobacillus delbrueckii subsp. lactis ATCC 15808 and its LL-H adsorption-resistant mutant, Ads-5, by hydrophobic interaction chromatography. L. delbrueckii phages (LL-H, the LL-H host range mutant, and JCL1032) were inactivated by these poly(glycerophosphate) type of LTAs in vitro in accordance to their adsorption to intact ATCC 15808 and Ads-5 cells.

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confidence: 57%

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confidence: 81%

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confidence: 99%

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confidence: 99%

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Characterization of Lipoteichoic Acids asLactobacillus delbrueckiiPhage Receptor Components

Räisänen

Schubert²,

Jaakonsaari

et al. 2004

J Bacteriol

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“…The LL-H gene product responsible for host recognition has been identified as Gp71 by utilizing the isolated LL-H-resistant mutant (Ads-5) of L. delbrueckii subsp. lactis ATCC 15808 and the LL-H host range mutants (35). The small isometric-headed phage LL-H, with a noncontractile tail, a baseplate, and a central tail fiber (5,21), exhibits only limited DNA similarity to another L. delbrueckii phage, JCL1032 (20,36).…”

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Molecular Interaction between Lipoteichoic Acids and Lactobacillus delbrueckii Phages Depends on d -Alanyl and α-Glucose Substitution of Poly(Glycerophosphate) Backbones

et al. 2007

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Lipoteichoic acids (LTAs) have been shown to act as bacterial counterparts to the receptor binding proteins of LL-H, LL-H host range mutant LL-H-a21, and JCL1032. Here we have used LTAs purified by hydrophobic interaction chromatography from different phage-resistant and -sensitive strains of Lactobacillus delbrueckii subsp. lactis. Nuclear magnetic resonance analyses revealed variation in the degree of ␣-glucosyl and D-alanyl substitution of the 1,3-linked poly(glycerophosphate) LTAs between the phage-sensitive and phage-resistant strains. Inactivation of phages was less effective if there was a high level of D-alanine residues in the LTA backbones. Prior incubation of the LTAs with ␣-glucose-specific lectin inhibited the LL-H phage inactivation. The overall level of decoration or the specific spatial combination of ␣-glucosyl-substituted, D-alanyl-substituted, and nonsubstituted glycerol residues may also affect phage adsorption.Multiplication of phages requires the takeover of the host cell metabolism. The phage infection starts when phages adsorb irreversibly to the specific surface structures of the host bacterium. The rate of adsorption depends on external factors like medium, pH, temperature, and cofactors (e.g., cations) (2). Phage-host interactions during host recognition and attachment between enterobacteria phages , T5, and P22 and outer membrane receptors have been studied thoroughly (10,11,25,40,45). Less is known about phage receptors of gram-positive bacteria (16,37). Accessory polymers of the cell wall (such as polysaccharides and wall teichoic acids) (12,14,16), the peptidoglycan layer (44), and a few membrane proteins (22, 37) have been identified to serve as receptors for some Listeria, Bacillus subtilis, Staphylococcus aureus, Lactococcus lactis, and Lactobacillus phages.Bacteriophages cause economic losses by disrupting lactic acid bacteria during milk fermentation before the desired texture and flavor have been formed in the product. Lactobacillus delbrueckii subsp. lactis and Lactobacillus delbrueckii subsp. bulgaricus are used as starters in cheese and yogurt production. The double-stranded DNA genome of the virulent phage LL-H (34.6 kb) is so far the only L. delbrueckii phage genome to be completely sequenced (29). The LL-H gene product responsible for host recognition has been identified as Gp71 by utilizing the isolated LL-H-resistant mutant (Ads-5) of L. delbrueckii subsp. lactis ATCC 15808 and the LL-H host range mutants (35). The small isometric-headed phage LL-H, with a noncontractile tail, a baseplate, and a central tail fiber (5, 21), exhibits only limited DNA similarity to another L. delbrueckii phage, JCL1032 (20, 36). The C-terminal end of ORF474 of JCL1032 shows, however, high sequence similarity to Gp71 (35). We have previously shown that lipoteichoic acids (LTAs) interact specifically with certain L. delbrueckii phages (34). LTAs most probably act as bacterial counterparts to the receptor binding proteins of LL-H, LL-H-a21, and JCL1032, thus representing a new class of phag...

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Interaction of phages, bacteria, and the human immune system: Evolutionary changes in phage therapy

Jariah

Hakim

2019

Reviews in Medical Virology

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Summary Phages and bacteria are known to undergo dynamic and co‐evolutionary arms race interactions in order to survive. Recent advances from in vitro and in vivo studies have improved our understanding of the complex interactions between phages, bacteria, and the human immune system. This insight is essential for the development of phage therapy to battle the growing problems of antibiotic resistance. It is also pivotal to prevent the development of phage‐resistance during the implementation of phage therapy in the clinic. In this review, we discuss recent progress of the interactions between phages, bacteria, and the human immune system and its clinical application for phage therapy. Proper phage therapy design will ideally produce large burst sizes, short latent periods, broad host ranges, and a low tendency to select resistance.

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A Conserved C-Terminal Region in Gp71 of the Small Isometric-Head Phage LL-H and ORF474 of the Prolate-Head Phage JCL1032 Is Implicated in Specificity of Adsorption of Phage to Its Host, Lactobacillus delbrueckii

Cited by 38 publications

References 30 publications

Characterization of Lipoteichoic Acids asLactobacillus delbrueckiiPhage Receptor Components

Characterization of Lipoteichoic Acids asLactobacillus delbrueckiiPhage Receptor Components

Molecular Interaction between Lipoteichoic Acids and Lactobacillus delbrueckii Phages Depends on d -Alanyl and α-Glucose Substitution of Poly(Glycerophosphate) Backbones

Interaction of phages, bacteria, and the human immune system: Evolutionary changes in phage therapy

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